cleaner code

[imago.git] / gridf.py

diff --git a/gridf.py b/gridf.py
index 51b0266..d39bdd5 100644 (file)
--- a/gridf.py
+++ b/gridf.py
@@ -1,6 +1,11 @@
+"""Imago grid-fitting module"""
+
+import multiprocessing
+

 import Image, ImageDraw, ImageFilter
 
 import Image, ImageDraw, ImageFilter
 

-from manual import lines as g_grid, l2ad, intersection, line as g_line
+from geometry import V, projection
+from manual import lines as g_grid, l2ad

 from intrsc import intersections_from_angl_dist
 from linef import line_from_angl_dist
 import pcf
 from intrsc import intersections_from_angl_dist
 from linef import line_from_angl_dist
 import pcf


@@ -16,175 +21,100 @@ class MyGaussianBlur(ImageFilter.Filter):
     def filter(self, image):
         return image.gaussian_blur(self.radius)
 
     def filter(self, image):
         return image.gaussian_blur(self.radius)
 

-class V(object):
-    def __init__(self, x, y):
-        self.x = x
-        self.y = y
-    
-    def __add__(self, other):
-        return V(self.x + other.x, self.y + other.y)
-
-    def __sub__(self, other):
-        return V(self.x - other.x, self.y - other.y)
-
-    def __rmul__(self, other):
-        return V(other * self.x, other * self.y)
-
-    def __len__(self):
-        return 2;
-
-    def __getitem__(self, key):
-        if key == 0:
-            return self.x
-        elif key == 1:
-            return self.y
-        elif type(key) != int:
-            raise TypeError("V indices must be integers") 
-        else:
-            raise KeyError("V index ({}) out of range".format(key))
-
-    def __iter__(self):
-        yield self.x
-        yield self.y
-
-    @property
-    def normal(self):
-        return V(-self.y, self.x)
-
-def projection(point, line, vector):
-    return V(*intersection(g_line(point, point + vector.normal), g_line(*line)))
+def job_br1(args):
+    X, Y, im_l, a, b, c, d, s, v1, v2, k, hough, size = args
+    return [(distance(im_l, 
+             get_grid(a + X[y] * s * v1, 
+                      b + Y[y] * s * v1, 
+                      c, d, hough, size),
+             size), a + X[y] * s * v1, b + Y[y] * s * v1) for y in range(2 *k)]
+
+def job_br2(args):
+    X, Y, im_l, a, b, c, d, s, v1, v2, k, hough, size = args
+    return [(distance(im_l, 
+             get_grid(a, b, c + X[y] * s * v2, 
+                      d + Y[y] * s * v2, 
+                      hough, size),
+             size), c + X[y] * s * v2, d + Y[y] * s * v2) for y in range(2 *k)]
+
+def find(lines, size, l1, l2, bounds, hough, do_something, im_h):
+    a, b, c, d = [V(*a) for a in bounds]
+    l1 = line_from_angl_dist(l1, size)
+    l2 = line_from_angl_dist(l2, size)
+    v1 = V(*l1[0]) - V(*l1[1])
+    v2 = V(*l2[0]) - V(*l2[1])
+    a = projection(a, l1, v1) 
+    b = projection(b, l1, v1) 
+    c = projection(c, l2, v2) 
+    d = projection(d, l2, v2) 
+
+    im_l = Image.new('L', size)
+    dr_l = ImageDraw.Draw(im_l)
+    for line in sum(lines, []):
+        dr_l.line(line_from_angl_dist(line, size), width=1, fill=255)
+
+    #im_l = im_h #hocus pocus    
+    im_l = im_l.filter(MyGaussianBlur(radius=2))
+    #GaussianBlur is undocumented class, may not work in future versions of PIL
+    im_l_s = im_l.tostring()
+
+    #from gridf_analyzer import error_surface
+    #error_surface(im_l, a, b, c, d, hough, size, v1 ,v2)
+
+    grid = get_grid(a, b, c, d, hough, size)

     
     

-def error_surface(lines, a, b, c, d, hough, size, v1):
-    import matplotlib.pyplot as plt
-    from matplotlib import cm
-    import threading
-    import Queue
-    import time
-    import sys
-    import pickle
-
-    class Worker(threading.Thread):
-        def __init__(self, q_in, q_out, job):
-            threading.Thread.__init__(self)
-            self.q_in = q_in
-            self.q_out = q_out
-            self.job = job
-
-        def run(self):
-            while True:
-                x = self.q_in.get()
-                try:
-                    self.q_out.put((x, self.job(x)))
-                except Exception:
-                    pass
-                print x
-                self.q_in.task_done()
-
-    X = []
-    Y = []
-    Z = []
+    #let's try the bruteforce aproach:

     s = 0.001
     s = 0.001

-    k = 200
+    k = 50
+    X, Y = [], []

     for i in range(-k, k):
         X.append(range(-k, k))
         Y.append(2*k*[i])
 
     for i in range(-k, k):
         X.append(range(-k, k))
         Y.append(2*k*[i])
 

-    job = lambda x: [distance(lines, get_grid(a + X[x][y] * s * v1, 
-                                              b + Y[x][y] * s * v1, 
-                                              c, d, hough, size),
-                                size) for y in range(0,2 * k)]
-
-    q_in = Queue.Queue()
-    q_out = Queue.Queue()
-    for i in range(4):
-        t = Worker(q_in, q_out, job)
-        t.daemon = True
-        t.start()
-        
-    start = time.time()
-    for x in range(0, 2*k):
-        q_in.put(x)
+    pool = multiprocessing.Pool(None)

 
 

-    q_in.join()
+    tasks = [(X[x], Y[x], im_l_s, a, b, c, d, s, 
+              v1, v2, k, hough, size) for x in xrange(0, 2 * k)]

 
 

+    import time
+    start = time.time()
+    opt_ab = pool.map(job_br1, tasks, 1)
+    opt_cd = pool.map(job_br2, tasks, 1)
+    d1 = 0
+    for lst in opt_ab:
+        for tpl in lst:
+            if tpl[0] > d1:
+                d1 = tpl[0]
+                a, b = tpl[1], tpl[2]
+    d1 = 0
+    for lst in opt_cd:
+        for tpl in lst:
+            if tpl[0] > d1:
+                d1 = tpl[0]
+                c, d = tpl[1], tpl[2]

     print time.time() - start
     print time.time() - start

+    grid = get_grid(a, b, c, d, hough, size) 
+    grid_lines = [[l2ad(l, size) for l in grid[0]], 
+                  [l2ad(l, size) for l in grid[1]]]
+    
+    ### 

 
 

-    while True:
-        try:
-            Z.append(q_out.get_nowait())
-        except Queue.Empty:
-            break
+    im_t = Image.new('RGB', im_l.size, None)
+    im_t_l = im_t.load()
+    im_l_l = im_l.load()
+    for x in xrange(im_t.size[0]):
+        for y in xrange(im_t.size[1]):
+            im_t_l[x, y] = (im_l_l[x, y], 0, 0)

 
 

-    Z.sort()
-    Z = [t for (x, t) in Z]
+    #im_t_d = ImageDraw.Draw(im_t)
+    #for l in grid[0] + grid[1]:
+    #    im_t_d.line(l, width=1, fill=(0, 255, 0))

 
 

-    s_file = open('surface' + str(k), 'w')
-    pickle.dump((X, Y, Z), s_file)
-    s_file.close()
-    plt.imshow(Z, cmap=cm.gnuplot2, interpolation='bicubic', 
-               origin='upper', extent=(-k, k, -k, k), aspect='equal')
-    plt.colorbar()
+    #do_something(im_t, "lines and grid")

 
 

-    plt.show()

 
 

-    sys.exit()
+    ###

 
 

-def find(lines, size, l1, l2, bounds, hough, do_something):
-    a, b, c, d = [V(*a) for a in bounds]
-    l1 = line_from_angl_dist(l1, size)
-    l2 = line_from_angl_dist(l2, size)
-    v1 = V(*l1[0]) - V(*l1[1])
-    v2 = V(*l2[0]) - V(*l2[1])
-    a = projection(a, l1, v1) 
-    b = projection(b, l1, v1) 
-    c = projection(c, l2, v2) 
-    d = projection(d, l2, v2) 
-
-    #error_surface(lines, a, b, c, d, hough, size, v1)
-
-    grid = get_grid(a, b, c, d, hough, size)
-    dist = distance(lines, grid, size)
-    print dist
-   
-    s = 0.02
-    while True:
-        ts1 = [(s, 0), (-s, 0), (s, s), (-s, -s), (-s, s), (s, -s), (0, s),  (0, -s)]
-        grids = [(get_grid(a + t[0] * v1, b + t[1] * v1, 
-                           c, d, hough, size), t) for t in ts1]
-        distances = [(distance(lines, grid, size), 
-                      grid, t) for grid, t in grids]
-        distances.sort(reverse=True)
-        if distances[0][0] > dist:
-            dist = distances[0][0]
-            grid = distances[0][1]
-            t = distances[0][2]
-            a, b = a + t[0] * v1, b + t[1] * v1
-            print dist
-            s *= 0.75
-        else: 
-           break
-
-    print "---"
-
-    s = 0.02
-    while True:
-        ts1 = [(s, 0), (-s, 0), (s, s), (-s, -s), (-s, s), (s, -s), (0, s),  (0, -s)]
-        grids = [(get_grid(a, b, 
-                           c + t[0] * v2, d + t[1] * v2, hough, size), t) for t in ts1]
-        distances = [(distance(lines, grid, size), 
-                      grid, t) for grid, t in grids]
-        distances.sort(reverse=True)
-        if distances[0][0] > dist:
-            dist = distances[0][0]
-            grid = distances[0][1]
-            t = distances[0][2]
-            c, d = c + t[0] * v2, d + t[1] * v2
-            print dist
-            s *= 0.75
-        else:
-            break
-
-    grid_lines = [[l2ad(l, size) for l in grid[0]], [l2ad(l, size) for l in grid[1]]]

     return grid, grid_lines
 
 def get_grid(a, b, c, d, hough, size):
     return grid, grid_lines
 
 def get_grid(a, b, c, d, hough, size):


@@ -199,37 +129,22 @@ def get_grid(a, b, c, d, hough, size):
     grid = g_grid(corners)
     return grid
 
     grid = g_grid(corners)
     return grid
 

-def distance(lines, grid, size):
-    im_l = Image.new('L', size)
-    dr_l = ImageDraw.Draw(im_l)
-    for line in sum(lines, []):
-        dr_l.line(line_from_angl_dist(line, size), width=1, fill=255)
-    im_l = im_l.filter(MyGaussianBlur(radius=15))
-    #GaussianBlur is undocumented class, may not work in future versions of PIL
+def line_out(line, size):
+    for p in line:
+        if p[0] < 0 or p[0] > size[0] or p[1] < 0 or p[1] > size[1]:
+            return True
+    else:
+        return False
+
+def distance(im_l, grid, size):

     im_g = Image.new('L', size)
     dr_g = ImageDraw.Draw(im_g)
     for line in grid[0] + grid[1]:
         dr_g.line(line, width=1, fill=255)
     im_g = Image.new('L', size)
     dr_g = ImageDraw.Draw(im_g)
     for line in grid[0] + grid[1]:
         dr_g.line(line, width=1, fill=255)

+        if line_out(line, size):
+            return 0

     #im_g = im_g.filter(MyGaussianBlur(radius=3))
     #im_g = im_g.filter(MyGaussianBlur(radius=3))

+    #GaussianBlur is undocumented class, may not work in future versions of PIL

     #im_d, distance = combine(im_l, im_g)
     #im_d, distance = combine(im_l, im_g)

-    distance = pcf.combine(im_l.tostring(), im_g.tostring())
-    return distance
-
-def combine(bg, fg):
-    bg_l = bg.load()
-    fg_l = fg.load()
-    #res = Image.new('L', fg.size)
-    #res_l = res.load()
-
-    score = 0
-    area = 0
-
-    for x in xrange(fg.size[0]):
-        for y in xrange(fg.size[1]):
-            if fg_l[x, y]:
-                #res_l[x, y] = bg_l[x, y] * fg_l[x, y]
-                score +=  bg_l[x, y]
-                area += 1
-
-    #return res, float(score)/area
-    return None, float(score)/area
+    distance_d = pcf.combine(im_l, im_g.tostring())
+    return distance_d